Emerging materials for plasmon-assisted photoelectrochemical water splitting

Palyam Subramanyam , Bhagatram Meena , Vasudevanpillai Biju , Hiroaki Misawa , Challapalli Subrahmanyam
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引用次数: 28

Abstract

Energy production and environmental pollution are the two major problems the world is facing today. The depletion of fossil fuels and the emission of harmful gases into the atmosphere leads to the research on clean and renewable energy sources. In this context, hydrogen is considered an ideal fuel to meet global energy needs. Presently, hydrogen is produced from fossil fuels. However, the most desirable way is from clean and renewable energy sources, like water and sunlight. Sunlight is an abundant energy source for energy harvesting and utilization. Recent studies reveal that photoelectrochemical (PEC) water splitting has promise for solar to hydrogen (STH) conversion over the widely tested photocatalytic approach since hydrogen and oxygen gases can be quantified easily in PEC. For designing light-absorbing materials, semiconductors are the primary choice that undergoes excitation upon solar light irradiation to produce excitons (electron-hole pairs) to drive the electrolysis. Visible light active semiconductors are attractive to achieve high solar to chemical fuel conversion. However, pure semiconductor materials are far from practical applications because of charge carrier recombination, poor light-harvesting, and electrode degradation. Various heteronanostructures by the integration of metal plasmons overcome these issues. The incorporation of metal plasmons gained significance for improving the PEC water splitting performance. This review summarizes the possible main mechanisms such as plasmon-induced resonance energy transfer (PIRET), hot electron injection (HEI), and light scatting/trapping. It also deliberates the rational design of plasmonic structures for PEC water splitting. Furthermore, this review highlights the advantages of plasmonic metal-supported photoelectrodes for PEC water splitting.

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等离子体辅助光电化学水分解新材料
能源生产和环境污染是当今世界面临的两大问题。化石燃料的枯竭和有害气体的排放导致了对清洁和可再生能源的研究。在这种情况下,氢被认为是满足全球能源需求的理想燃料。目前,氢是由化石燃料产生的。然而,最理想的方式是从清洁和可再生能源,如水和阳光。太阳光是一种丰富的能量来源,可用于能量的收集和利用。最近的研究表明,光电化学(PEC)水分解比广泛测试的光催化方法更有希望将太阳能转化为氢(STH),因为在光电化学(PEC)中氢和氧的气体可以很容易地量化。在设计吸光材料时,半导体是首选材料,它在太阳光照射下激发产生激子(电子-空穴对)来驱动电解。可见光有源半导体是实现高太阳能到化学燃料转换的重要途径。然而,纯半导体材料由于电荷载流子复合、光收集不良和电极退化等问题,离实际应用还很遥远。金属等离子体的各种异质结构克服了这些问题。金属等离激元的加入对提高等离子体的水裂解性能具有重要意义。本文综述了等离子体诱导共振能量转移(PIRET)、热电子注入(HEI)和光散射/捕获等可能的主要机制。并对等离子体水分裂等离子体结构的合理设计进行了探讨。此外,本文还强调了等离子体金属支撑光电极用于PEC水分解的优点。
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来源期刊
CiteScore
21.90
自引率
0.70%
发文量
36
审稿时长
47 days
期刊介绍: The Journal of Photochemistry and Photobiology C: Photochemistry Reviews, published by Elsevier, is the official journal of the Japanese Photochemistry Association. It serves as a platform for scientists across various fields of photochemistry to communicate and collaborate, aiming to foster new interdisciplinary research areas. The journal covers a wide scope, including fundamental molecular photochemistry, organic and inorganic photochemistry, photoelectrochemistry, photocatalysis, solar energy conversion, photobiology, and more. It provides a forum for discussing advancements and promoting collaboration in the field of photochemistry.
期刊最新文献
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